Let's call a binary sequence *almost valid* if it starts with "1" and has at most `m`

consecutive "1" digits.

For `i = 1, ..., n`

and `j = 0, ..., m`

let `a(i, j)`

be the number of almost valid sequences with length `i`

that end with exactly `j`

consecutive "1" digits.

Then

`a(1, 1) = 1`

and `a(1, j) = 0 for j != 1`

, because "1" is the only almost valid sequence of length one.
- For
`n >= 2`

and `j = 0`

we have `a(i, 0) = a(i-1, 0) + a(i-1, 1) + ... + a(i-1, m)`

, because appending "0" to any almost valid sequence of length `i-1`

gives an almost valid sequence of length `i`

ending with "0".
- For
`n >= 2`

and `j > 0`

we have `a(i, j) = a(i-1, j-1)`

because appending "1" to an almost valid sequence with `i-1`

trailing ones gives an almost valid sequence of length `j`

with `i`

trailing ones.

Finally, the wanted number is the number of almost valid sequences with length `n`

that have a trailing "1", so this is

```
f(n, m) = a(n, 1) + a(n, 2) + ... + a(n, m)
```

Written as a C function:

```
int a[NMAX+1][MMAX+1];
int f(int n, int m)
{
int i, j, s;
// compute a(1, j):
for (j = 0; j <= m; j++)
a[1][j] = (j == 1);
for (i = 2; i <= n; i++) {
// compute a(i, 0):
s = 0;
for (j = 0; j <= m; j++)
s += a[i-1][j];
a[i][0] = s;
// compute a(i, j):
for (j = 1; j <= m; j++)
a[i][j] = a[i-1][j-1];
}
// final result:
s = 0;
for (j = 1; j <= m; j++)
s += a[n][j];
return s;
}
```

The storage requirement could even be improved, because only the last column of the matrix `a`

is needed. The runtime complexity is `O(n*m)`

.